A cushion ring sprocket assembly and chain drive system are designed to prevent roller-to-root radial contact. Hard contact between the chain link plates and the cushion rings, and corresponding hard contact between the cushion rings and the sprocket hubs limit radial inward movement of the chain rollers/bushings, while the root surfaces of the tooth spaces are undercut so that the rollers cannot contact the root surfaces.
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1. A sprocket assembly comprising:
a body including a ring of teeth and first and second hubs that project axially outward relative to opposite first and second faces of said ring of teeth, said first and second hubs defining respective first and second outside diameters each having a radius hr, and said ring of teeth comprising N teeth separated from each other by respective tooth spaces, said teeth each comprising engaging and disengaging flanks, wherein respective root surfaces are located between engaging and disengaging flanks of successive teeth, said sprocket body defining a chordal pitch p, a pitch diameter pd and a pitch chord radius RC and adapted to mesh with an associated chain having a link plate height Hp;
first and second sets of metal cushion rings eccentrically captured on said first and second hubs, respectively, said first and second sets of cushion rings having a radial thickness rt;
wherein:
wherein said root surfaces are each undercut relative to said pitch diameter pd so that rollers/bushings of the associated chain cannot contact the undercut root surfaces when said chain is in hard contact with respective outside diameter locations of said first and second sets of metal cushion rings and when said outside diameter locations are respectively radially aligned with respective inside diameter locations of said first and second sets of metal cushion rings that are respectively in hard contact with said first and second hubs.
4. A chain drive system comprising:
a sprocket assembly comprising: (i) a body including a ring of teeth and first and second hubs that project axially outward relative to opposite first and second faces of said ring of teeth, said first and second hubs defining respective first and second outside diameters, and said ring of teeth comprising a plurality of teeth separated from each other by respective tooth spaces, said teeth each comprising engaging and disengaging flanks, wherein respective root surfaces are located between engaging and disengaging flanks of successive teeth, wherein each of said root surfaces is undercut relative to a pitch diameter defined by said sprocket assembly body; (ii) first and second sets of metal cushion rings eccentrically captured on said first and second hubs, respectively;
a chain drivingly engaged with said sprocket assembly, said chain comprising: (i) first and second rollers/bushings located in first and second tooth spaces and fully meshed with said sprocket assembly such that respective centers of said first and second rollers/bushings are located on said pitch diameter; and, (ii) first and second link plates between which said first and second rollers/bushings are located, said first and second link plates including respective first and second link plate inner edges;
wherein respective first and second inside diameter contact locations of said first and second sets of cushion rings are in hard contact with said first and second hubs, respectively, and said first and second link plate inner edges are respectively in hard contact with first and second outside diameter locations of said first and second sets of cushion rings that are respectively radially aligned with said first and second inside diameter contact locations, such that first and second clearances are defined between said first and second fully meshed rollers/bushings and said first and second root surfaces, respectively.
2. The sprocket assembly as set forth in
3. The sprocket assembly as set forth in
5. The chain drive system as set forth in
6. The chain drive system as set forth in
7. The chain drive system as set forth in
first and second cushion ring sets define respective first and second radial thicknesses that are equal to each other;
a first swing radius is defined by a radius of said first hub outside diameter plus said first radial thickness of said first cushion ring set;
a second swing radius is defined by a radius of said second hub outside diameter plus said second radial thickness of said second cushion ring set; and,
said first and second clearances are defined when a midpoint of said first link plate inner edge is located radially at said first swing radius and when a midpoint of said second link plate inner edge is located radially at said second swing radius.
8. The chain drive system as set forth in
9. The chain drive system as set forth in
first and second cushion ring sets define respective first and second radial thicknesses that are equal to each other;
a first swing radius is defined by a radius of said first hub outside diameter plus said first radial thickness of said first cushion ring set;
a second swing radius is defined by a radius of said second hub outside diameter plus said second radial thickness of said second cushion ring set; and,
said first and second clearances are defined when a midpoint of said first link plate inner edge is located radially at said first swing radius and when a midpoint of said second link plate inner edge is located radially at said second swing radius.
10. The chain drive system as set forth in
11. The chain drive system as set forth in
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This application claims priority from and benefit of the filing date of U.S. provisional application Ser. No. 60/721,715 filed Sep. 29, 2005 and U.S. provisional application Ser. No. 60/834,015 filed Jul. 28, 2006, and both of said provisional applications are hereby expressly incorporated by reference into the present specification.
Sprockets incorporating metal cushion rings have been used in automotive engine roller chain drive systems such as camshaft and balance shaft drives. The purpose of the cushion rings is to buffer or soften the roller-sprocket collision at the onset of meshing, thereby acting to reduce the chain meshing noise levels associated with roller chain drive systems. Roller-sprocket impact at the onset of meshing is the dominant noise source associated with roller chain drive systems and it occurs when a chain link leaves the span and its meshing roller collides with the sprocket tooth at engagement. It is believed that multiple roller-sprocket tooth impacts occur during the meshing phenomena and these impacts contribute to the undesirable noise levels associated with roller chain drives. There will be at least two impacts at the onset of meshing, a radial impact as the roller collides with the root surface and a tangential impact as the roller moves into driving position. It is believed that radial impact(s) will occur first, followed closely by tangential impact(s).
With reference also to
It is important to note that the chain link pitch P for a minimum as-manufactured roller chain 40 will be equal to the chordal pitch P for a roller chain sprocket 20 having a maximum as-manufactured tooth form. As is well known in the art, this equality for chain pitch P and sprocket chordal pitch P exists only at the aforementioned limits of the manufacturing tolerance range, and as the relevant chain and sprocket tolerances vary toward the opposite end of their respective manufacturing limits, there will be a pitch mismatch between chain link pitch which is more specifically designated PC and sprocket chordal pitch which is more specifically designated PS, with PC>PS. In other words, chain link pitch PC will always be greater than sprocket chordal pitch PS except at the specified manufacturing tolerance limit as noted. For the purpose of the included figures, chain link pitch is equal to sprocket chordal pitch, and accordingly, all rollers in the wrap angle θ for the conventional cushion ring sprockets will contact the root surface 24 of sprocket teeth 22 at the root diameter RD (see
As shown in
Referring now to
This initial radial meshing impact IR is normally the major contributor to the overall chain drive noise level, and the utilization of a conventional metal cushion ring sprocket notwithstanding, radial meshing impacts will still occur—albeit reduced impacts—along with the corresponding objectionable noise levels associated with roller-sprocket meshing impacts. Accordingly, it has been deemed desirable to develop a new and improved cushion ring sprocket to further reduce the noise levels associated with roller chain drives.
In accordance with one aspect of the present invention, a sprocket assembly includes a body including a ring of teeth and first and second hubs that project axially outward relative to opposite first and second faces of the ring of teeth. The first and second hubs define respective first and second outside diameters each having a radius HR, and the ring of teeth includes N teeth separated from each other by respective tooth spaces. Each tooth includes engaging and disengaging flanks, wherein respective root surfaces are located between engaging and disengaging flanks of successive teeth. The sprocket body is adapted to mesh with an associated roller chain having a link plate height HP and a pitch P such that said sprocket body defines a pitch diameter PD and a pitch chord radius RC. First and second sets of metal cushion rings are eccentrically captured on the first and second hubs, respectively. The first and second sets of cushion rings each have a radial thickness RT. The sprocket assembly satisfies the relationships:
wherein said root surfaces are undercut so that rollers/bushings of the associated chain cannot contact the root surfaces.
In accordance with another aspect of the present invention, a chain drive system includes a sprocket assembly with a body including a ring of teeth and first and second hubs that project axially outward relative to opposite first and second faces of the ring of teeth. The first and second hubs define respective first and second outside diameters. The ring of teeth includes a plurality of teeth separated from each other by respective tooth spaces. The teeth each include engaging and disengaging flanks, wherein respective root surfaces are located between engaging and disengaging flanks of successive teeth. First and second sets of metal cushion rings are eccentrically captured on the first and second hubs, respectively. A chain is drivingly engaged with the sprocket assembly. The chain includes: (i) first and second rollers located in first and second tooth spaces and fully meshed with said sprocket assembly; and, (ii) first and second roller link plates between which said first and second rollers are located. The first and second roller link plates include respective first and second link plate inner edges. The first and second sets of cushion rings position said first and second roller link plates such that first and second clearances are defined between said first and second fully meshed rollers and first and second root surfaces of the first and second tooth spaces, respectively.
In accordance with another aspect of the present invention, a method of meshing a chain with a sprocket assembly includes: rotating a sprocket body of the sprocket assembly such that successive roller link rows of a roller chain move into engagement with the sprocket body; contacting first and second roller link plates of each successive roller link row with first and second eccentric metal cushion ring sets of the sprocket assembly, respectively, to radially position first and second rollers of each successive roller link row in first and second tooth spaces as the roller link row moves into and through a wrap angle; limiting radial inward movement of the first and second rollers of each successive roller link row by hard contact between the first and second roller link plates and the first and second cushion ring sets, and by hard contact between the first and second eccentric cushion ring sets with respective first and second hubs such that first and second clearances are defined between the first and second rollers and respective first and second root surfaces of the first and second tooth spaces for all positions of the roller link row in the wrap angle.
In accordance with another aspect of the present invention, a sprocket assembly includes a body including a ring of teeth and first and second hubs, the first and second hubs defining respective first and second outside diameters, and the ring of teeth comprising a plurality of teeth separated from each other by respective tooth spaces. The teeth each include an engaging and disengaging flank, wherein respective root surfaces are located between engaging and disengaging flanks of successive teeth. First and second metal cushion rings are eccentrically captured on the first and second hubs, respectively. The first and second hubs and said first and second metal cushion rings are dimensioned to radially position an associated chain on the body, wherein said root surfaces are undercut such that rollers/bushings of the associated chain cannot contact said root surfaces.
The invention comprises various components and arrangements of components, preferred embodiments of which are illustrated in the accompanying drawings wherein:
The present invention is directed to an improved cushion ring sprocket system 110 and/or sprocket assembly 115 to provide reduced roller chain drive meshing noise levels. Except as otherwise shown and/or described, the system 110, chain 140 and sprocket assembly 115 are identical to the system 10, chain 40 and sprocket assembly 15 described above, and corresponding components are identified with reference numbers that are 100 greater than those used above.
Referring to
As described above in relation to the conventional cushion ring sprocket assembly, those of ordinary skill in the art will recognize that the chain link pitch P for a minimum as-manufactured roller chain 140 will be equal to the chordal pitch P for a roller chain sprocket 120 having a maximum as-manufactured tooth form. As is also well known in the art, this equality for chain pitch P and sprocket chordal pitch P exists only at the aforementioned limits of the manufacturing tolerance range and, as the relevant chain and sprocket tolerances vary toward the opposite end of their respective manufacturing limits, i.e., as the chain link pitch P (which is more specifically designated PC) lengthens relative to its theoretical minimum and as the sprocket chordal pitch P (which is more specifically designated PS) shortens relative to its theoretical maximum there will be a pitch mismatch between chain link pitch PC and sprocket chordal pitch PS, with PC>PS. In other words, chain link pitch PC will always be greater than sprocket chordal pitch PS except at the specified manufacturing tolerance limit as noted. For the purpose of the included figures, chain link pitch PC is shown to be equal to sprocket chordal pitch PS. Also, a roller 150 is deemed to be fully meshed and seated in its driving position when its center is located on the pitch diameter PD and when the roller 150 is making flank contact FC with an engaging flank 122a of a tooth 122.
Except as otherwise shown and/or described herein, the sprocket body 120 is identical to the conventional sprocket body 20 disclosed above and such conventional features of the sprocket body 120 are not necessarily detailed again in this detailed description. In particular, it is noted that the sprocket body 120 includes a recess or bore B as shown in
Referring still to
The sprocket assembly 115 comprises first and second cushion rings 130 manufactured from a metal such as bearing-grade steel that float eccentrically on first and second hubs 125a, 125b adjacent first and second opposite tooth faces/walls 121a, 121b (
Referring now to
With continuing reference to
Where pitch chord radius RC (
where:
HR=Hub radius
RT=Cushion ring thickness
RC=Pitch circle chord radius
HP=Link plate height
PD=Pitch diameter
P=Pitch
N=Number of sprocket teeth
Those of ordinary skill in the art will note the only variables are HR and RT—all other factors, i.e., the pitch circle chord radius RC, the chain link plate height HP, the pitch diameter PD, the chain/sprocket pitch P, and the number of sprocket teeth N, will always be determined independently. Furthermore, RT will be determined as a function of the chain tension and drive dynamics.
With specific reference again to
More specifically, referring first to
Each set of cushion rings 330a, 330b is dimensioned so that when the rings 330a, 330b are fully deflected, i.e., when there is hard contact between the inner and outer rings 330a, 330b, and also hard contact between the inner rings 330a and the outer diameters 326a, 326b of hubs 325a, 325b, the chain rollers 150 associated with link plates 146, 148 that are in hard contact with the outer cushion rings 330b cannot make radial contact with the undercut root surface 324. In such case, the ring sets 330a, 330b ensure that a chain roller 150 can never make radial contact with the root surface 324. In particular, the hub radius HR2 and the combined thickness of the multiple cushion rings RT2 defines a swing radius when the rings are in hard contact with each other and when the innermost ring 330a on each side of the sprocket is in hard contact with the respective hub 325a, 325b. As described above, the swing radius is dimensioned by controlling the hub radius HR2 and combined ring thickness RT2 such that when inner edges of chain link plates 146, 148 are located at the swing radius (at the midpoints of the link plates), the centers of the chain rollers 150 are located on the pitch diameter and the rollers are spaced above the respective root surfaces 324.
This multiple ring configuration permits greater total ring deflection, resulting in reduced transverse vibration in the chain span and better chain span control since the chain link plates will contact the outer cushion rings 330b earlier in the meshing process as the chain approaches the sprocket to provide an initial damping of the movement of the rollers 150, while the inner cushion rings 330a complete the damping process in a staged fashion. The enhanced chain span control results in reduced roller-sprocket impact at the onset of meshing. Multiple rings also allow the cushioning effect of the ring sets 330a, 330b to be tuned for specific chain drive applications. As mentioned above, only the outer rings 330b deflect initially to provide the initial damping rate, until their inside diameters come into contact with the outside diameters of the inner rings 330a, respectively, and at this point the damping rate will increase since both rings must then deflect in order for the chain to continue to move radially inward. Another main advantage of this multiple cushion ring configuration is the increased damping without corresponding increases in stress in the cushion rings 330a, 330b.
The invention has been described with reference to preferred embodiments. Modifications and alterations will occur to those of ordinary skill in the art to which the invention pertains, and it is intended that the invention be construed as encompassing all such modifications and alterations according to the following claims as construed literally and/or according to the doctrine of equivalents.
Patent | Priority | Assignee | Title |
10400869, | Sep 02 2016 | Tsubakimoto Chain Co. | Chain drive mechanism |
10578201, | Jul 03 2015 | SRAM DEUTSCHLAND GmbH | Sprocket wheel for a bicycle drive |
10703441, | Jul 03 2015 | SRAM DEUTSCHLAND GmbH | Drive arrangement for a bicycle |
11353102, | Jul 03 2015 | SRAM DEUTSCHLAND GmbH | Sprocket wheel for a bicycle drive |
11884363, | Jul 03 2015 | SRAM DEUTSCHLAND GmbH | Sprocket wheel for a bicycle drive |
8979689, | Feb 21 2008 | Ludwig Dierl | Synchronous flat belt drive |
9933063, | Dec 05 2013 | OGNIBENE S P A | Silent sprocket/gear for transmission chains, in particular for motorcycles, and mold components for its production |
9957852, | Jun 14 2016 | DELPHI TECHNOLOGIES IP LIMITED | Cushion ring assembly for a sprocket driven by a chain |
Patent | Priority | Assignee | Title |
2492219, | |||
2953930, | |||
3057219, | |||
3448629, | |||
3523463, | |||
4082372, | Jan 26 1976 | Caterpillar Mitsubishi Ltd. | Noise reducing device for a track chain arrangement |
4227422, | May 19 1978 | Honda Giken Kogyo Kabushiki Kaisha | Chain device |
4261214, | Jun 02 1977 | Honda Giken Kogyo Kabushiki Kaisha | Chain noise preventing device |
4348199, | Oct 04 1979 | Honda Giken Kogyo Kabushiki Kaisha | Buffer device for a roller chain and sprocket coupling |
5224903, | Jun 18 1991 | Firma Carl Freudenberg | Chain wheel having a shrink ring made of a polymer material |
5360378, | Sep 14 1992 | Tsbakimoto Chain Co. | Chain drive mechanism having improved noise reduction |
5397278, | Jun 30 1993 | Tsubakimoto Chain Co. | Sprocket for roller chain |
6371874, | May 27 1999 | Tsubakimoto Chain Co. | Sprocket equipped with cushion body |
6419604, | Dec 24 1998 | Tsubakimoto Chain Co. | Double-meshing-type silent chain drive and sprocket used therein |
6652402, | Sep 02 2000 | SCHAEFFLER CHAIN DRIVE SYSTEMS SAS | Chain drive |
6910980, | Mar 18 2002 | HH-CLOYES, INC | Cushion ring sprocket assembly and method |
20030176251, | |||
20040185977, | |||
20040204274, | |||
20050170925, | |||
20060160648, | |||
DE10025736, | |||
DE19929667, | |||
DE19961046, | |||
GB2086817, | |||
JP57186654, | |||
JP57190160, | |||
WO3089814, | |||
WO2004059194, |
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